Passive high frequency image reject mixer

ABSTRACT

The apparatus is a complete passive implementation of an image reject mixer (IRM) that is capable of operating at very high frequency. Using a hybrid as part of the IRM circuit enables operation at very high frequencies that also employs a high intermediate frequency (IF). All the components of the design are passive and implementable in MOS technologies providing significant cost and implementation advantages. Furthermore, the apparatus is operative at frequencies that are higher than several tens of GHz.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims the benefit of U.S. Provisional Patent Application No. 61/213,756 filed Jul. 10, 2009.

STATEMENT OF SUPPORT

The work that led to the development of this invention was co-financed by Hellenic Funds and by the European Regional Development Fund (ERDF) under the Hellenic National Strategic Reference Framework (NSRF) 2007-2013, according to Contract no. MIKRO2-34 of the project “Next Generation Millimeter Wave Backhaul Radio-THETA”, within the Program “Hellenic Technology Clusters in Microelectronics-Phase-2 Aid Measure”.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates generally to image reject mixers, and more specifically to image reject mixers operating at frequencies reaching several tens of gigahertz and above.

2. Prior Art

As wireless communication progresses, the frequency of operation increases dramatically. Currently frequencies of tens of GHz are employed and are expected to increase over time. Operation at high frequencies is also known to be demanding in power as well as technology. That is, for the same design, the higher the frequency of operation the higher the power consumption. The higher frequency range also requires use of more esoteric manufacturing technologies, such as GaAs, that are capable of effectively addressing the frequency requirements, but such manufacturing technologies have a price from both a technology and a power perspective. As long as demand for such products is low, such technologies are tolerated, but as the need for mass production arises, it is required to utilize technologies that are more power friendly as well as less esoteric.

In order to reduce costs, there is a tendency to move from a more expensive process technology to a lower cost process technology, e.g., moving from GaAs to CMOS. However, a lower cost technology, such as CMOS, may suffer from other disadvantages. In the area of image reject mixers (IRMs) targeted to operate at frequencies in the range of tens of GHz, CMOS based technologies are not currently used, and hence the advantages associated with such technologies are not achieved. Moreover, active components are used, with the Gilbert cell being the prominent solution. An alternative approach is shown in FIG. 1. The MOS down-conversion multiplier mixer 100 comprises a quad MOS cell 110 and a transresistance amplifier 120 that is used to convert the mixer output current to voltage signal. Together with the capacitors 130, it further acts as a low-pass filter in order for only the intermediate frequency (IF) to pass through. The quad MOS cell 110 is a balanced mixer operative as a multiplying mixer. The RF signal at the input of the mixer is multiplied by the local oscillator (LO) signal. The low-pass filter of this circuit 100 cuts-off the RF+LO product while maintaining the IF RF−LO frequency.

The current art is limited because of its inability to provide frequency mixers that are low on power consumption, are implemented on cost-effective integrated circuit (IC) technologies, and are capable of operating at high intermediate (IF) frequencies, preferably in the GHz range. It would therefore be advantageous to provide a solution that overcomes the prior art limitations.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a multiplying down-conversion mixer (prior art).

FIG. 2 is a schematic diagram of a passive IRM implemented in accordance with the principles of the invention.

FIG. 3 is a hybrid element used as an element of the passive IRM.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The apparatus of the present invention is a complete passive implementation of an image reject mixer (IRM) that is capable of operating at very high frequency. Using a hybrid as part of the IRM circuit enables operation at very high frequencies that also employ a high intermediate frequency (IF). All the components of the design are passive and implementable in MOS technologies providing significant cost and implementation advantages. Furthermore, the apparatus is operative at frequencies that are higher than several tens of GHz.

In accordance with the principles of the invention, the mixer solution, depicted in FIG. 1, is modified as an IRM where the filtering action implemented with a transresistance amplifier is replaced by a lumped-element hybrid. The hybrid, further described in FIG. 3 below, functions as both a band-pass filter and as the image rejection apparatus. The result is a fully passive circuit that does not require a bias current for its operation. Reference is now made to FIG. 2 that depicts a schematic diagram of the passive IRM 200 implemented in accordance with the principles of the invention. Basically it comprises quad MOS elements 110 (110-1 and 110-2, also see FIG. 1), typically operative in the deep triode region, a phase shifter 220 and hybrids 230. The purpose of the image-reject mixer 200 is to reject the image (IM) signal that is down-converted. Present are a RF signal and a local oscillator (LO) signal. The IM signal is IM=RF+2*IF. Hence, if RF<LO, then IF=LO−RF and IM=RF+2*IF=RF+2*(LO−RF)=2*LO−RF. When it is down-converted this becomes: 2*LO−RF−LO=LO−RF=IF. In other words, there is a product from the unwanted frequency IM falling into the IF signal and it is therefore necessary to distinguish the wanted RF from the unwanted IM. The solution is to use the IRM and in accordance with the invention, to use the hybrid. Accordingly the first output of the hybrid carries the IF component that comes from the wanted RF frequency and the second hybrid output carries the IF component coming from the IM frequency. It is the positioning of the RF signal with respect to the LO signal that defines which output carries which product. This requires determination whether RF is greater than LO or RF is smaller than LO and there upon selecting the desired output from the hybrid, as further shown with respect to FIG. 3.

The passive mixer (passive meaning incapable of or at least not providing gain) and hybrid combination shown in FIG. 2 not only provides image rejection but also acts like a passive filter to reject the high-frequency component (RF+LO) and eliminates the need for current to voltage conversion as the hybrids are current-driven directly from the quad MOS transistors.

Notably, the MOS cell 110 of FIG. 2 operates as a multiplying mixer, where the output is a multiplication of the radio frequency (RF) by the local oscillator (LO), or in other words RF×LO, resulting in an output of both RF+LO and RF−LO frequencies. Multipliers 110 hence receive the differential RF signals RF+ and RF−. In addition multiplier 110-1 receives the differential LO signals LO+ and LO− while the multiplier 110-2 receives the same LO signals with a 90° phase shift using phase shifter 220. The phase shifter 220, according to the invention, is a passive element, and in a typical implementation, a Lange coupler, implemented in a silicon-based technology, may be used. Accordingly, multiplier 110-1 outputs the “I IF+” and “I IF−” differential signals and multiplier 110-2 outputs the “Q IF+” and “Q IF−” differential signals. The outputs from the multipliers 110-1 and 110-2 are provided to lumped-element hybrids 230. A detailed description of a lumped-element 230 is provided with respect to FIG. 3 below. The “I IF+” output from multiplier 110-1 and the “Q IF+” output of multiplier 110-2 are provided to the inputs of hybrid 230-1. The “I IF−” output of multiplier 110-1 and the “Q IF−” output of multiplier 110-2 are provided to the inputs of the hybrid 230-2. The hybrids 230 provide the wanted “IF+” and the wanted “IF−” signals at the outputs of hybrids 230-1 and 230-2 respectively, and are further explained below with respect to FIG. 3.

To further understand the principles of the invention, reference is made to FIG. 3, depicting a lumped-element hybrid 230. The hybrid 230 comprises four inductors and four capacitors designed to mimic the behavior of a classical microwave Branchline coupler, without using MMIC technologies. The “I” input of the hybrid 230 is coupled to one port of the capacitor 234-1, the other port of which is connected to ground. Also coupled to the “I” input are two inductors, inductor 232-1 and 232-4. The other terminal of inductor 232-1 is coupled to the “Q” input of hybrid 230 as well as to terminals of capacitor 234-2, the other port of which is connected to ground, and to inductor 232-2. The other port of inductor 232-4 is coupled to the terminal 237 of the hybrid 230 as well as to terminals of capacitor 234-3, the other port of which is connected to ground, and inductor 232-3. The other ports of inductors 232-2 and 232-3 are coupled to each other as well as to a port of capacitor 234-4, the other port of which is coupled to ground, and to the terminal 238 output of hybrid 230. A switch 236 determines which of the signals present at terminals 237 and 238 is the “wanted IF” signal and accordingly connects that terminal to the IF_(O) output of the hybrid 230. The switch has a first position when RF>LO and a second position when RF<LO. In one embodiment of the invention, one or more of the capacitors 234 are tunable, thereby allowing tuning of the hybrid. For this purpose, a switched capacitor bank (not shown) or a variable capacitor (not shown) may be used, both of which are well known in the prior art, resulting in a variable hybrid 230. In an exemplary application with an IF above 1 gigahertz, such as an IF in the range of 1-7 GHz, the inductor range is 1-6 nH and the capacitor range is 1-6 pF. Inductors and capacitors in these ranges are readily and reasonably implementable in common manufacturing technologies such as CMOS technology, thereby allowing for cost-effective implementation of such integrated circuits (ICs). Furthermore, using the hybrid 230 at the output of the IRM 200 removes the need of having an operational amplifier at the output of the mixer as required by prior art solutions. In another embodiment, the IF is above 5 gigahertz.

In one embodiment of the invention (FIG. 2), a set of switches (not shown) may be connected immediately at the hybrid output enabling a selection of only one of the two outputs each time. The hybrid 230-1 provides the final IF+ and the hybrid 230-2 provides the final IF−. The reason for using both terminals 237 and 238 of the hybrid, or having them available in the first place, is that it allows different treatment of the output signal when the RF frequency is greater than the LO frequency than when the LO frequency is greater than the RF frequency. By having the switches at the hybrid outputs, the appropriate output terminal can be selected depending on the frequency plan of operation of the receiver chain. This is of course unnecessary if the frequencies are fixed for a given system, as in such a case one of the two outputs can be used without employing switches. The other output may be simply connected to ground through a 50 Ohm resistor. In yet another embodiment, the “I” and “Q” outputs of the two IF signals may be added to convert the differential output to one single IF output having a double amplitude. The appropriate hybrid output has the image (IM) component suppressed and this is the image-reject operation of the mixer. In accordance with the invention, the hybrids 230 have a double role: they operate as a band-pass filter to reject the RF+LO mixer output component and as an IM rejection component.

The complete passive implementation of the IRM provides significant advantage for low power implementations and especially the use of pervasive CMOS manufacturing technologies. Specifically, it allows an implementation of the IRM for very high frequencies, for example, a 90 nanometer CMOS technology allows for a 60 GHz IRM, otherwise not implementable in such a technology. The use of the hybrid 230 enables high-frequency IF, in the range of a few GHz, a range which is compatible with an RF frequency as high as 60 GHz. Using prior art solutions, the combination of an active mixer with a hybrid would not be operative for such a high RF. Vice versa, the combination of a passive mixer with an operational amplifier instead of the hybrid, is not suitable for such an IF range. Hence the invention overcomes the deficiencies of the prior art. By further using a Lange coupler to implement the phase shifter in combination with the MOS switches and the hybrids, all for an all in a Silicon-based process, without compromising the performance necessary for a mixer operative in an RF range of several tens of GHz and an IF in the range of several GHz, and implementing the circuit on an IC.

While certain preferred embodiments of the present invention have been disclosed and described herein for purposes of illustration and not for purposes of limitation, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention. Specifically, the circuit disclosed is applicable to any Silicon-based manufacturing process, including MOS, BiCMOS and CMOS processes. The upper limit of the RF is determined by the process geometry. 

1. A passive image reject mixer (IRM) comprising: a first MOS multiplier enabled to receive RF+ and RF− input signals forming differential radio frequency input signal and LO+ and LO− input signals forming a differential local oscillator input signal, and further enabled to output an intermediate frequency I IF+ and I IF− differential output signal; a second MOS multiplier; a passive phase shifter coupled to said differential local oscillator input signal and enabled to output to said second MOS multiplier said differential local oscillator input signal phase shifted ninety degrees; the second MOS multiplier enabled to receive said differential radio frequency input signal and the output of the passive phase shifter, and further enabled to output an intermediate frequency (IF) Q IF+ and Q IF− differential output signal; a first lumped-element hybrid coupled to receive said I IF+ output signal of said first MOS multiplier and said Q IF+ output signal of said second MOS multiplier, said first lumped-element hybrid being enabled to output an IF+ output signal responsive to whether a frequency of said radio frequency input signal is greater or less than a frequency of said first differential local oscillator input signal; and a second lumped-element hybrid coupled to receive said I IF− output signal of said first MOS multiplier and said Q IF− output signal of said second MOS multiplier, said second lumped-element enabled to output an IF− output signal responsive to whether a frequency of said radio frequency input signal is greater or less than a frequency of said first differential local oscillator input signal; said first MOS multiplier and said second MOS multiplier both being operative in deep triode region.
 2. The passive IRM of claim 1, wherein said IRM is operative with an intermediate frequency above one gigahertz.
 3. The passive IRM of claim 1, wherein said IRM is operative with an intermediate frequency above five gigahertz.
 4. The passive IRM of claim 1, wherein each said lumped-element hybrid comprises: a first capacitor, having a first terminal coupled to an I input of said lumped-element hybrid; a second capacitor, having a first terminal coupled to a Q input of said lumped-element hybrid; a third capacitor, having a first terminal coupled to a first input of a two-to-one switch of said lumped-element hybrid; a fourth capacitor, having a first terminal coupled to a second input of said two-to-one switch of said lumped-element hybrid; a first inductor coupled between said I input and said first input of said two-to-one switch; a second inductor coupled between said Q input and said second input of said two-to-one switch; a third inductor coupled between said I input and said Q input; a fourth inductor coupled between said first input of said two-to-one switch and said second input of said two-to-one switch; and said two-to-one switch being coupled to an IF output terminal of said lumped-element hybrid and enabled to select between said first input of said two-to-one switch and said second input of said two-to-one switch responsive to whether a frequency of said differential radio frequency input signal is greater than or lower than a frequency of the differential local oscillator input signal.
 5. The passive IRM of claim 4, wherein at least one of said first capacitor, said second capacitor, said third capacitor and said fourth capacitor is enabled to be tuned to provide variable capacitance.
 6. The passive IRM of claim 4, wherein at least one of said first capacitor, said second capacitor, said third capacitor and said fourth capacitor is a switched capacitor bank comprising a plurality of capacitors.
 7. The passive IRM of claim 4, wherein in each said lumped-hybrid, each of said first capacitor, said second capacitor, said third capacitor and said fourth capacitor has a capacitance in the range of one to six pico-Farads.
 8. The passive IRM of claim 4, wherein in each said lumped-hybrid, each of said first inductor, said second inductor, said third inductor and said fourth inductor has an inductance in the range of one to six nano-Henry.
 9. The passive IRM of claim 1, wherein in each said lumped-hybrid, each said passive phase shifter is a Lange coupler.
 10. The passive IRM of claim 1, wherein the passive IRM is manufactured using one of: MOS processing technology, CMOS processing technology, BiCMOS process technology.
 11. A passive image reject mixer (IRM) comprising: a differential radio frequency input signal having RF+ and RF− input signals; a first differential local oscillator input signal having LO+ and LO− input signals; a second differential local oscillator signal phase shifted with respect of said first differential local oscillator input signal, the second differential local oscillator signal providing phase shifted LO+ and LO− signals; a first passive multiplier responsive to said RF+ and said RF− input signals, said LO+ and said LO− input signals, and outputting I IF+ and an “I IF− output signals; a second passive multiplier responsive to said RF+ and said RF− input signals, said phase shifted LO+ and said phase shifted LO− signals, and outputting a Q IF+ and Q IF− output signals; a first passive filter for filtering said I IF+ and said Q IF+ output signals and generating an IF+ output signal; and a second passive filter filtering said I IF− and said Q IF− signals and generating an IF− output signal.
 12. The passive IRM of claim 11, further comprised of a passive phase shifter coupled to receive said first differential local oscillator input signal and provide said second differential local oscillator signal.
 13. The passive IRM of claim 12, wherein said passive phase shifter is a Lange coupler.
 14. The passive IRM of claim 11, wherein said phase shifter shifts said phase ninety degrees.
 15. The passive IRM of claim 11, wherein said first passive multiplier comprises four MOS transistors wherein gates of two of said four MOS transistor are coupled to said LO+ signal and gates of the other two of said four MOS transistor are coupled to said LO− signal, and wherein said second passive multiplier comprises four MOS transistors wherein gates of two of said four MOS transistor are coupled to said phase shifted LO+ signal and gates of the other two of said four MOS transistor are coupled to said phase shifted LO− signal.
 16. The passive IRM of claim 11, wherein each said passive filter comprises a lumped-element hybrid.
 17. The passive IRM of claim 16, wherein each said lumped-element hybrid comprises: a first capacitor, having a first terminal coupled to an I input of said lumped-element hybrid; a second capacitor, having a first terminal coupled to a Q input of said lumped-element hybrid; a third capacitor, having a first terminal coupled to a first input of a two-to-one switch of said lumped-element hybrid; a fourth capacitor, having a first terminal coupled to a second input of a two-to-one switch of said lumped-element hybrid; a first inductor coupled between said I input and said first input of a two-to-one switch; a second inductor coupled between said Q input and said second input of a two-to-one switch; a third inductor coupled between said I input and said Q input; and a fourth inductor coupled between said first input of said two-to-one switch and said second input of said two-to-one switch; an output of each said two-to-one switch being coupled to a respective IF output terminal of said lumped-element hybrid and enabled to select between said first input of the respective said two-to-one switch and said second input of the respective said two-to-one switch responsive to whether a frequency of said radio frequency input signal is greater or less than a frequency of said first differential local oscillator input signal.
 18. The passive IRM of claim 17, wherein in each said lumped-element hybrid, at least one of said first capacitor, said second capacitor, said third capacitor and said fourth capacitor of each said is enabled to be tuned to provide variable capacitance.
 19. The passive IRM of claim 17 wherein in each said lumped-element hybrid, at least one of said first capacitor, said second capacitor, said third capacitor and said fourth capacitor is a switched capacitor bank comprising a plurality of capacitors.
 20. The passive IRM of claim 17, wherein in each said lumped-element hybrid, each of said first capacitor, said second capacitor, said third capacitor and said fourth capacitor has a capacitance in the range of one to six pico-Farads.
 21. The passive IRM of claim 17, wherein in each said lumped-element hybrid, each of said first inductor, said second inductor, said third inductor and said fourth inductor has an inductance in the range of one to six nano-Henry.
 22. The passive IRM of claim 11, wherein a frequency of said IF+ and IF− output signals is at least one gigahertz.
 23. The passive IRM of claim 11, wherein a frequency of said IF+ and IF− output signals is at least five gigahertz. 